Piezoelectric Aluminium Scandium Nitride (AlScN) Thin Films: Material Development and Applications in Microdevices

Piezoelectric Aluminium Scandium Nitride (AlScN) Thin Films: Material Development and Applications in Microdevices

Recently, aluminium scandium nitride (AlScN) emerged as a material with superior properties compared to aluminium nitride (AlN). Substituting Al with Sc in AlN leads to a dramatic increase in the piezoelectric coefficient as well as in electromechanical coupling. This discovery finally allowed us to...

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Bibliographic Details
Other Authors: Žukauskaitė, Agnė (Editor)
Format: Electronic Book Chapter
Language:English
Published: Basel MDPI - Multidisciplinary Digital Publishing Institute 2023
Subjects:
Research & information: general
Physics
AlN
AlScN
aluminum nitride
aluminum scandium nitride
micromirror
microscanner
piezoelectric
aluminium scandium nitride
piezoelectric thin films
MEMS
non-metallic substrates
scandium-doped aluminum nitride
ferroelectric
substrate-RF
residual stress
coercive field
leakage current
high temperature
nonvolatile memory
retention
fatigue
wurtzite
film
sputter deposition
scandium-aluminum nitride
Lamb-wave resonators
complementary switchable
SAW devices
piezoelectricity
ScAlN thin film
diamond thin film
5G technology
electromechanical coupling coefficient k2
Q-factor
aluminum scandium nitride (AlScN)
aluminum nitride (AlN)
wet etch
potassium hydroxide (KOH)
physical vapor deposition
stress
stress gradient
fabrication
cantilever beams
thermal stability
structure analysis
X-ray diffraction
ferroelectrics
thin film
PUND test
laser ultrasound
surface acoustic waves
magnetron sputter epitaxy
elastic properties
thin films
piezoelectric films
Raman spectroscopy
alloy scattering
temperature coefficient
n/a
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Description
Summary:Recently, aluminium scandium nitride (AlScN) emerged as a material with superior properties compared to aluminium nitride (AlN). Substituting Al with Sc in AlN leads to a dramatic increase in the piezoelectric coefficient as well as in electromechanical coupling. This discovery finally allowed us to overcome the limitations of AlN thin films in various piezoelectric applications while still enabling us to benefit from all of the advantages of the parent material system, such as a high temperature stability, CMOS compatibility, and good mechanical properties. Potential applications include RF filters (bulk acoustic wave (BAW) or surface acoustic wave (SAW) resonators), energy harvesting, sensing applications, and infra-red detectors. The recent progress in MOCVD- and MBE-grown AlScN has led to high-frequency and -power electronics, (high-electron-mobility transistors (HEMTs)). AlScN is the first wurtzite III-nitride where ferroelectric switching was observed, allowing for many new possible applications in semiconductor memories additionally, it enables the additional functionality of switching to applications where piezoelectric materials are already in use. This Special Issue was very successful in covering all of the main aspects of AlScN research, including its growth, the fundamental and application-relevant properties, and device fabrication and characterization. We can see that AlScN technology is mature enough to be utilized in wafer-level material development and complicated devices, but there is still much to discover in terms of deposition process control, anisotropy, and, in particular, ferroelectric behavior.
Physical Description:1 electronic resource (186 p.)
ISBN:books978-3-0365-6366-4
9783036563671
9783036563664
Access:Open Access

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